Investigation on gas migration in saturated materials with low permeability

Xu, Long; Ye, Weimin; Ye, Bin; Bao, Changchun; Chen, Yong-Gui; Cui, Yu‐Jun

doi:10.1016/j.enggeo.2015.08.019

Cited by 42 publications

(4 citation statements)

References 33 publications

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“…Wettability heterogeneity may also impact the magnitude of fluctuations due to the associated energy dissipation (Murison et al, 2014). Also, fluctuations are stronger for a gas-liquid system and more often reported explicitly (Alkan and Müller, 2008;Reynolds and Krevor, 2015;Xu et al, 2015;Spurin et al, 2020), which suggests that viscosity ratio may be an important factor, which has been also reported in (Spurin et al, 2019).…”

Section: Introductionmentioning

confidence: 89%

The Origin of Non-thermal Fluctuations in Multiphase Flow in Porous Media

et al. 2021

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Core flooding experiments to determine multiphase flow in properties of rock such as relative permeability can show significant fluctuations in terms of pressure, saturation, and electrical conductivity. That is typically not considered in the Darcy scale interpretation but treated as noise. However, in recent years, flow regimes that exhibit spatio-temporal variations in pore scale occupancy related to fluid phase pressure changes have been identified. They are associated with topological changes in the fluid configurations caused by pore-scale instabilities such as snap-off. The common understanding of Darcy-scale flow regimes is that pore-scale phenomena and their signature should have averaged out at the scale of representative elementary volumes (REV) and above. In this work, it is demonstrated that pressure fluctuations observed in centimeter-scale experiments commonly considered Darcy-scale at fractional flow conditions, where wetting and non-wetting phases are co-injected into porous rock at small (<10−6) capillary numbers are ultimately caused by pore-scale processes, but there is also a Darcy-scale fractional flow theory aspect. We compare fluctuations in fractional flow experiments conducted on samples of few centimeters size with respective experiments and in-situ micro-CT imaging at pore-scale resolution using synchrotron-based X-ray computed micro-tomography. On that basis we can establish a systematic causality from pore to Darcy scale. At the pore scale, dynamic imaging allows to directly observe the associated breakup and coalescence processes of non-wetting phase clusters, which follow “trajectories” in a “phase diagram” defined by fractional flow and capillary number and can be used to categorize flow regimes. Connected pathway flow would be represented by a fixed point, whereas processes such as ganglion dynamics follow trajectories but are still overall capillary-dominated. That suggests that the origin of the pressure fluctuations observed in centimeter-sized fractional flow experiments are capillary effects. The energy scale of the pressure fluctuations corresponds to 105-106 times the thermal energy scale. This means the fluctuations are non-thermal. At the centimeter scale, there are non-monotonic and even oscillatory solutions permissible by the fractional flow theory, which allow the fluctuations to be visible and—depending on exact conditions—significant at centimeter scale, within the viscous limit of classical (Darcy scale) fractional flow theory. That also means that the phenomenon involves both capillary aspects from the pore or cluster scale and viscous aspects of fractional flow and occurs right at the transition, where the physical description concept changes from pore to Darcy scale.

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Section: Introductionmentioning

confidence: 89%

The Origin of Non-thermal Fluctuations in Multiphase Flow in Porous Media

et al. 2021

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“…This results in the presence of weathered soil fragments, a potential sediment resource for wind transportation and the subsequent formation of dust storms (Pye & Tsoar, 2008; Style et al., 2011; Yesiller et al., 2000; Zielinski, et al., 2014). For environmental sites, such as landfills and reservoirs of radioactive nuclear waste, clay‐based soils establish multiple barriers that separate the waste from the biosphere (Ng et al., 2015; Xu et al., 2015). Owing to the repeated drying‐wetting paths, the formation of soil cracks impairs the long‐term protection functionality of the barrier, causing the possible leakage of toxic volatile gases and liquids, as reported in previous studies (Albrecht & Benson, 2001; Du et al., 2022, 2021; Kalkan, 2009; Ma et al., 2019; Rayhani et al., 2007; Seiphoori et al., 2014; Ye et al., 2020).…”

Section: Introductionmentioning

confidence: 99%

Investigating Soil Desiccation Cracking Using an Infrared Thermal Imaging Technique

Zhou

Tang

Zhu

et al. 2021

Water Resources Research

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“…Hydraulic conductivity is one of the most important and useful parameters in the study of the seepage process of porous media [1] and plays a vital role in the research of consolidation, settlement of soils and foundation, rheology [2][3][4][5], dewatering design [6][7][8], migration of gas and liquid [9][10][11], sandstone storage [12][13][14][15], storage of CO 2 and nuclear waste [16][17][18][19][20], and other geological and geotechnical engineering problems. Generally, it is difficult to measure dynamic variation of the hydraulic conductivity by experimental means.…”

Section: Introductionmentioning

confidence: 99%

Prediction Method for Hydraulic Conductivity considering the Effect of Sizes of Ellipsoid Soil Particles from the Microscopic Perspective

Shen

Zhu

2019

Advances in Civil Engineering

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In the existing research studies of hydraulic conductivity, most of them assume that soil consists of spheroidal particles and the value of hydraulic conductivity can be designated by the particle size. In the actual soil layers, the shape of soil particles is mostly ellipsoid or rod-like rather than ideal sphere. Therefore, the prediction of soil permeability using current method often deviates from the actual situation and cannot capture the anisotropy nature of soil without consideration of the effect of the axis size of soil particles in two different directions. To solve this problem, a new theoretical model with three different soil particle arrangements is introduced to derive a new hydraulic conductivity-particle size relationship considering the size difference in two directions. This model, from a microscopic perspective, divides pores into numerous pore units and obtains hydraulic conductivity of each tube unit, eventually predicting the permeability of soil layer based on an equivalence principle. The proposed equation is validated in comparison with experimental data from the existing literature and is proved to have a satisfied accuracy to predict hydraulic conductivity for a wide range of soils, from bentonite-silt mixed soils to sandy soils. The proposed model provides a new perspective for accurately predicting the hydraulic conductivity.

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Investigation on gas migration in saturated materials with low permeability

Cited by 42 publications

References 33 publications

The Origin of Non-thermal Fluctuations in Multiphase Flow in Porous Media

The Origin of Non-thermal Fluctuations in Multiphase Flow in Porous Media

Investigating Soil Desiccation Cracking Using an Infrared Thermal Imaging Technique

Prediction Method for Hydraulic Conductivity considering the Effect of Sizes of Ellipsoid Soil Particles from the Microscopic Perspective

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